Optimization of bandgap reduction in 2-dimensional GO nanosheets and nanocomposites of GO/iron-oxide for electronic device applications

In this report we have developed different fabrication parameters to tailor the optical bandgap of graphene oxide (GO) nanosheets to make it operational candidate in electronic industry. Here we performed two ways to reduce the bandgap of GO nanosheets. First, we have optimized the oxidation level of GO by reducing amount of oxidizing agent (i.e. KMnO4) to control the sp2/sp3 hybridization ratio for a series of GO nanosheets samples. We noticed the reduction in primary band edge 3.93–3.2 eV while secondary band edge 2.98–2.2 eV of GO nanosheets as the amount of KMnO4 is decreased from 100 to 30%. Second, we have fabricated a series of 2-dimensional nanocomposites sample containing GO/Iron-oxide by using a novel synthesis process wet impregnation method. XRD analysis of synthesized nanocomposites confirmed the presence of both phases,\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\alpha$$\end{document}α-Fe2O3 and Fe3O4 of iron-oxide with prominent plane (001) of GO. Morphological investigation rules out all the possibilities of agglomerations of iron oxide nanoparticles and coagulation of GO nanosheets. Elemental mapping endorsed the homogeneous distribution of iron oxide nanoparticles throughout the GO nanosheets. Raman spectroscopy confirmed the fairly constant ID/IG ratio and FWHM of D and G peaks, thus proving the fact that the synthesis process of nanocomposites has no effect on the degree of oxidation of GO flakes. Red shift in G peak position of all the nanocomposites samples showed the electronic interaction among the constituents of the nanocomposite. Linear decrease in the intensity of PL (Photoluminescence) spectra with the increasing of Iron oxide nanoparticles points towards the increased interaction among the iron oxide nanoparticles and GO flakes. Optical absorption spectroscopy reveals the linear decrease in primary edge of bandgap from 2.8 to 0.99 eV while secondary edge decrease 3.93–2.2 eV as the loading of \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\alpha$$\end{document}α-Fe2O3 nanoparticles is increased from 0 to 5% in GO nanosheets. Among these nanocomposites samples 5%-iron-oxide/95%-GO nanosheet sample may be a good contestant for electronic devices.

www.nature.com/scientificreports/ compositional analysis and optical properties. Optical bandgap of GO is highly dependent on the sp 2 /sp 3 hybridization ratio of carbon atoms. Theoretically if we could somehow control the degree of oxidation during the synthesis of GO its optical bandgap could be controlled. This reduction of optical band-gap can be credited to electronic interactions between the composite materials during synthesis process.

Results and discussion
X-ray diffraction analysis. To analyze the phase formation of GO nanosheets and interplanar distance for our samples, we performed X-ray Diffraction (XRD) measurements. Figure 1a shows the XRD crystal spectra of as synthesized GO samples. We observed that most prominent plane (001) correspond to GO with another minor peak related to (002) plane of graphite as reported earlier 23 . It is also noted that the peak intensity peak of GO (001) plane increases as we increase the concentration of KMnO 4 from 20 to 100% while overall the opposite trend of graphitic (002) plane is observed. This observation clearly indicates that at higher concentration of KMnO 4 more single prominent GO phase formation is stabilized. The variation in peak positions of GO (001) plane is more elaborated as revealed inset of Fig. 1a, may be owing to the different degree of oxidation. It is observed that (001) plane shifts toward higher 2 θ as the amount of oxidant is decreased. Ayrat group 24 explained these two phases and reported that oxidation of graphite flake starts from the edge and moves toward the center. www.nature.com/scientificreports/ them surrounded by sp 3 hybridized GO. This results in the presence of both GO and graphite in the diffraction spectra of the samples. The crystallite thickness is measured and demonstrated in Fig. 1b. We observed that crystallite thickness is highest (~ 10.5 nm) for 40%-KMnO 4 and smallest (~ 6 nm) for 100%-KMnO 4 concentrations. Peak position of (001) plane and interplanar distance of controlled oxidized GO nanosheets samples are showing opposite behavior with increasing %ages of KMnO 4 as presented in Fig. 1c. As the amount of KMnO 4 is increased may be greater functional groups gets attached to the basal plane thus enlarged the interplanar distance as stated by Marcano et al. 23 . Here we may argue the increase in d-spacing with an increase in the amount of oxidizing agent. In other words we can say that with the increase in oxidizing agent, d-spacing increases so possibly sp 2 to sp 3 hybridization ratio may decrease which may be responsible for increasing the optical bandgap of these nanosheets GO samples. Figure 1Sa represents the XRD spectra of analytical grade Graphite powder of Sigma-Aldrich. This XRD spectra shows three significant peaks at 26.38 • , 44.25 • and at 54.54 • identified as (002), (101) and (004) planes of graphite respectively according to the JCPDS card no 01-075-1621. To get information regarding oxidation level and the effects of chemical processes performed throughout the synthesis of GO and its nanocomposites, determination of interplanar distance (d) is of great importance, so Graphite sample is used as a reference for that purpose. For the determination of interplanar distance Bragg's law is used 25 . Here θ is the one half of peak diffraction angle, d is the interplanar distance, represents the Cu K(α) wavelength, which in our case is 1.54 Å and n is the mode of vibration. For all the analysis second mode of vibration is used. The interplanar distance calculated is 0.337 nm for (002) plane and 0.358 nm for (004) plane, these values corresponds to the JCPDS card no 01-075-1621. In order to calculate the number of layer in the crystallite, L c lattice parameter in z-axis or the crystallite height is required. Scherer's equation can be used to calculate the crystallite height for graphitic materials because of their planner structure [25][26][27][28][29][30] . In this relation 0.89 is the Scherrer's constant used for L c of graphitic materials, is the wavelength of Cu K(α), β is the graphically calculated full width and half maxima of the peak. Average crystallite height is found ~ 26.78 nm for pure graphite. To find out the number of layers lattice spacing "d" and crystallite height "L c " is used in the following relation According to this relation, there are around 151 layers in an average graphite crystallite. Figure 1Sb shows the XRD spectra of as synthesized GO flakes carried out at 2 θ value of 5 • to 70 • . A single prominent peak at 9.88° is identified to be as (001) plane of GO. Peak position and intensity corresponds to the earlier reported values 23 . Inter-planner distance calculated with the help of Bragg's law showed a substantial increase in "d" spacing from 0.33 nm of Graphite to 0.885 nm of GO. This rise in inter planar distance is because of the hydroxyl and epoxy functional groups attached on the basil plane of honey comb lattice of graphite during its chemical exfoliation 23 . These functional groups make bonds with the Π electrons of the carbon atoms. This results in the change in hybridization of carbon atoms from sp 2 to sp 3 . This change of hybridization alters the band gap of the material, zero band gap Graphite becomes semiconductor with a band gap ranging to about 3.7 eV. Degree of oxidation or the amount of functional groups attached to the basal plane of GO could be easily monitored with the help of inter planner distance. Higher oxidation levels leads toward the increased d-spacing and vice versa. This d-spacing also identifies any kind of reduction in GO in reduction process functional groups gets removed from the basal plane of GO thus in turn causing the interplanar distance to decrease. Scherrer's formula gives the approximated L c value of 6.099 nm for as-synthesized GO nanosheets. Here we can see a substantial decrease in crystallite thickness as compared to its precursor. This decreased crystallite thickness is an indicator for a successful chemical exfoliation. This exfoliation is carried by the exothermic oxidation reaction. We found that instead of 151 layers in untreated commercial grade Graphite; GO only have about 7 layers of sp 3 hybridized carbon atoms. The XRD spectra of as synthesized iron oxide nanoparticles obtained as given in Fig. 1Sc. After very careful analysis it is found that as synthesized iron oxide nanoparticles contained α-Fe 2 O 3 and Fe 3 O 4 phases by comparing with JCPDS card no-65-3107 and 89-0598. Both phases of iron oxide in pure nanoparticles sample have been marked in Fig. 1Sc. Presence of Fe 3 O 4 in the specimen is because of the further oxidation of α-Fe 2 O 3 during the synthesis process. Crystallite size for these Iron oxide nanoparticles is found with the help of Scherrer's equation. Analysis reveals the presence of nanoparticles in the specimen with an average size of 28.1 nm.
XRD spectra of GO/iron-oxide nanocomposites synthesized by using "wet impregnation technique" are shown in Fig. 2a for various compositions of 0.25, 3, 5 and 7% Iron-oxide concentration. Presence of (001) characteristic peak of GO at 9.6 • indicates the fact that no reduction of GO (i.e. r-GO) is carried out during the nanocomposite synthesis process 23   Micro-structural properties. To observe the morphology, the elemental distribution of nanocomposites and regional reduction of graphene oxide flakes during nanocomposite synthesis Field Emission Scanning Electron Microscopy (FE-SEM) and energy dispersive spectroscopy (EDS) measurements were performed for entire series of GO nanosheets samples and GO/Iron-oxide nanocomposites samples. Figure 3a-d represents the SEM images of GO nanosheets at different scale (a) 20-μm (b)10-μm (c) 5-μm (d) 2-μm. We observed that nanosheets are not fully separated from each other but still agglomeration was present at small scale. These GO flakes were further exposed to EDS to know the elemental composition. This study provides valuable information about the elemental composition of GO. The EDS spectra and elemental mapping of GO nanosheets had been demon- www.nature.com/scientificreports/ strated in Fig. 4. Here we noted that GO nanosheets sample showed the presence of higher amount of carbon and oxygen. Presence of Sulfur and chlorine is because of Sulfuric acid and hydrochloric acid used in the synthesis scheme whereas silicon is because of the impurities present in the precursor graphite 31 . Hydrogen present in hydroxyl functional groups attached on the basal plane of GO flakes is undetectable because of its lower atomic mass. The percentage presence of normal concentration and atomic concentration is given accordingly in table inset EDS spectra (Fig. 4). Figure 5a-d is the SEM images of GO/Iron-oxide nanocomposites at 500 nm scale for various concentrations of iron oxides (a) 0.25% (b) 3% (c) 5% (d) 7%. We noted the agglomeration among nanosheets. GO flakes are evenly decorated with iron oxide nanoparticles. More concentration of nanoparticles of iron oxide is visible in Fig. 5d i.e. 93%GO/7%-Iron-oxide nanocomposites as compared to Fig. 5a i.e. 99.75%GO/0.25%-Iron-oxide nanocomposites sample. Any sign of reduction is not present in any of the sample, thus proving the results of XRD. GO flakes are fully oxidized and have around 25-32 nm thickness. Particle size of iron oxide nanoparticles and sheet thickness of GO flakes observed with the help of SEM images are in accordance to the XRD results. The EDS spectrum and elemental analysis of 95%GO/5%-Iron-oxide nanocomposites sample had been presented in Fig. 6. The EDS spectrum represents very prominent peaks of carbon, oxygen and iron. Generic impurities of GO, silicon and sulfur are also present in the spectrum 31 . Elemental mapping and atomic percentages of these constituent elements are demonstrated in Fig. 6. Even distributions of oxygen atoms throughout the flake rules out any chance of regional reduction of GO caused by the synthesis process or due to the oxidation of α-Fe 2 O 3 . Atomic percentages of these constituent elements are shown in table inset EDS spectra (Fig. 6). Higher carbon to oxygen ratio proves the XRD results that no reduction of GO is carried out during the nanocomposite formation. Sulfur is because of sulfuric acid used in the synthesis of GO and silicon is present in the nanocomposites because silicon based compounds are found in the graphite used as a starting material for GO synthesis.

Raman spectroscopy.
To identify the degree of oxidation and to observe the un-oxidized domain size variation during the controlled oxidation of GO nanosheets samples and GO/Iron-oxide nanocomposites samples, Raman spectroscopic measurements were accomplished at room temperature with LASER excitation wave- www.nature.com/scientificreports/ length of 514 nm. Raman spectra for various samples of GO nanosheets with varying KMnO 4 concentrations for entire range 400-3000 cm −1 had been exhibited in Fig. 7a. The spectrum of each sample reveals the presence of D, G and 2D characteristics peaks of GO nanosheets as reported previously [9][10][11][12][13][14][15][16][17][18][19] . The peak at 1366 cm −1 position corresponds to D-band that may be assigned by A 1g mode of vibrations. The formation of D-band is probably due to the defect generated phonon mode vibrations or disorderness in the honeycomb graphitic structures such as vacancies, bond-angle disorder, edge defects and bond-length disorder [32][33][34][35] . Another reason of D-band can be the presence of hydroxyl and epoxide functional groups on the basal plane of GO nanosheets 36 . Another most prominent peak at 1617 cm −1 position linked with G-band that may be caused by the first order C-C stretching vibrations of E 2g phonons observed for sp 2 carbon domains 35,[37][38][39] . Moreover, another 2D peak is observed at 2755 cm −1 and it is assigned to second-order zone boundary phonons or to a two phonon double resonance process 40 .  Fig. 7b. From this analysis we noted that FWHM values of both bands increases as % age of KMnO 4 increases. On getting this information we may propose that degree of oxidation may increase as FWHM of D and G bands increase. In previous studies, FWHM of D-band of GO is directly related to the degree of oxidation because the oxidation process has a direct effect on sp 2 /sp 3 ratio 41 i.e. the reduction of sp 2 /sp 3 hybridization ratio of GO flakes. Similarly, the FWHM of G-band also increased with increasing the degree of oxidation level of GO nanosheets 42 . We found the I D /I G ratio reflected opposite trend as that of FWHM of bands with the increase of % ages of KMnO 4 . The I D /I G ratio of GO nanosheets is also associated with the degree of oxidation and in-plane sp 2 domain size 38,41 . As the degree of oxidation increases I D /I G ratio decreases representing the decrease in in-plane sp 2 domain size. On the basis of above Raman results we may argue that degree of oxidation in GO samples increased as we increased the KMnO 4 concentrations in samples.
Raman spectrum of Iron oxide nanoparticles is demonstrated in Fig. 8a. We analyzed the spectroscopic data and found that both phases of α-Fe 2 O 3 and Fe 3 O 4 are present as we extracted from XRD data. The characteristics peaks at positions of 271, 389.8, 485 and 1302 cm −1 represents the α-Fe 2 O 3 phase while the peaks at 208 and 591.5 cm −1 belongs to Fe 3 O 4 as reported in previous studies [43][44][45] . Peaks at 208 and 591 cm −1 corresponds to A 1g mode of vibrations while the remaining peaks except the one at 1302 cm −1 are assigned to E g mode of vibrations and the peak at 1308 cm −1 corresponds to the two magnon scattering caused by the interaction of two magnons created on anti-parallel close spin sites inconsistent as reported in literature 46 . Figure 8b reflects the Raman spectra of GO and GO/Iron-oxide nanocomposites. Owing to the lower concentration of iron oxide nanoparticles, no characteristic peaks of iron oxide is visible in any of the Raman spectra of GO/Iron-oxide nanocomposites samples. Analysis to these spectra reveals the presence of D-band (1366 cm −1 ) is assigned to the A 1g , G-band (1617 cm −1 ) is caused by the first order C-C stretching vibrations of E 2g phonons observed for sp 2 carbon domains and 2D characteristics peaks (2755 cm −1 ) assigned to second-order zone boundary phonons or to a two phonon double resonance process of GO as reported in previously [32][33][34][35][36][37][38][39][40] . We measured the FWHM of D-peak is found to www.nature.com/scientificreports/ be 167 cm −1 and FWHM of G-peak is found to be 107 cm −1 for GO/Iron-oxide nanocomposites samples which correspond to reported values previously [32][33][34][35][36][37][38][39][40] . G-band position of GO and GO/Iron-oxide nanocomposites had been plotted in Fig. 8c. Position of the G-band in Graphene based nanosheets systems is an ideal marker to study the interaction among nanomaterials. To check that whether our GO/Iron-oxide nanocomposites samples with proper electronic interaction is made or not, positions of G-band are compared. We found a red shift in the peak position of G-band as with increasing the Iron-oxide concentration in GO nanosheets structures. Similarly, electronic interaction between the carbon based materials and nanoparticles causes the G-band to red shift [47][48][49][50][51][52][53] . This red shift becomes greater as the interaction among the constituents of the nanocomposite increases a linear red shift in G-band position could be seen in Fig. 8c as the loading of iron oxide nanoparticles is increased from 0.25 to 7%. This analysis gives us information that iron oxide nanoparticles are not just resting on the basal plane of GO nanosheets but they are electronically interacting with each other. Figure 8d showed the extracted data of intensity as well ratio of D and G peaks (I D /I G ) ratio of GO/Iron-oxide nanocomposites samples while in general the I D /I G ratio in GO nanosheets is inversely proportional to the degree of oxidation and in-plane sp 2 domain size. As the degree of oxidation decreases I D /I G ratio increases representing an increase in in-plane sp 2 domain size 38,41 . This fairly similar I D /I G ratio points towards the fact that no reduction of GO nanosheets is carried out during the synthesis process of nanocomposite nor by the chemical reaction Photoluminescence spectroscopy. Photoluminescence (PL) spectra is a well-known technique to study transfer process of the interface charge carrier as well as the recombination process involving the electron-hole pairs in semiconductor systems [59][60][61] and PL emission results from the radiative recombination of excited electrons and holes. Room temperature (RT) PL spectrum of few selected controlled GO nanosheets samples with varying oxidizing agent is presented in Fig. 9a, while Fig. 9b showed RT PL spectrum of GO (i.e. 100% KMnO 4 ), iron oxide nanoparticles and GO/Iron-oxide nanocomposites samples. We noted that the nanosheets based on GO systems showed strong PL intensity at wavelength of ~ 420 nm as reported earlier 62 . This high intensity represents the high recombination rate of photo generated charge carriers. While we observed that Iron oxide nanoparticles on the other hand do not show any PL intensity in this region. PL spectra of 95%GO-5% iron oxide and 93% GO-7% iron oxide nanocomposites represented in Fig. 9b gives us a great insight about understanding the electronic interaction among the iron oxide nanoparticles and GO flakes. Another interesting result we noticed that the PL intensity of the GO/Iron-oxide nanocomposites decreased with the increasing mass ratios of iron oxide nanoparticles, indicating that the recombination of photo generated electron-hole pairs is efficiently hindered. Our data from Fig. 10b reflects that 5% nanocomposite shows relatively lesser PL intensity as compared www.nature.com/scientificreports/ to the pure GO but for only 2% more loading as compared to 5% nanocomposite, 7% iron oxide-GO nanocomposite shows a drastic decrease in PL intensity, meaning the better separation of photo generated charge carriers.

Optical absorption studies. To identify the optical bandgap of synthesized GO nanosheets samples, UV-
Visible absorption spectrophotometry at room temperature was carried out in the range of 190-700 nm. Figure 10a represented absorption spectra of a series of well controlled oxidized GO nanosheets samples for various concentrations of KMnO 4. Similarly, we have obtained the UV-Visible absorption data for the series of GO/ Iron-oxide nanocomposite samples as demonstrated in Fig. 11a. From absorption data we noted that overall more prominent and sharp absorption occurred around ~ 226 nm and this sharp peak represents the ordered graphitic structure with a π → π * transition of aromatic C=C bonds present in the GO structure 63,64 . Another less intense absorption band occurred at ~ 300 nm that reported previously for n → π * transition and commonly assigned to either C-O-C bonds or C=O bonds and therefore provides evidence for oxygen functionality on the GO sheets [63][64][65] . We were unable to measure the absorption spectra of GO (20% KMnO 4 ) sample. The reduced amount of oxidizing agent may have induced the hydrophobic behavior in GO nanosheets that may decrease sp 2 /sp 3 ratio in this sample, which eliminates the ability of this sample to get dispersed in deionized water. In all the specimens of controlled oxidized GO samples no absorption peak is observed in the range of 400-500 nm. Existence of absorption peaks in this region corresponds to KMnO 4 62 . To calculate the optical bandgap from this absorption data linear extrapolation of Tauc plot is used 66 as; where α the absorption coefficient, h is the frequency of light, A is proportionality constant, E g is the band-gap energy, and n is the type of electron excitation. Its value is different for direct and indirect band transition. Usually, "n" is 1/2 for direct bandgap and 2 for indirect bandgap transitions 67,68 . In our case we are only concerned with direct band to band transition of electron. Tauc plot of each controlled oxidized GO samples and GO/ Iron-oxide nanocomposite samples have been extracted from absorption data and revealed in Figs. 10b and 11b respectively. We found and measured two distinct bandgap for each GO sample as reported earlier 63,69 . We denoted these bandgap with names primary edge (higher values of bandgap) and secondary edge (lower values of bandgap) as presented in Figs. 10b and 11b respectively for controlled oxidized GO samples and GO/Ironoxide nanocomposite samples. www.nature.com/scientificreports/ We noticed that both edges of each sample are increasing with increasing the concentration of KMnO 4 as displayed in Fig. 10c. It was found that owing to the crude nature of the synthesis of GO nanosheets degree of oxidation of no two flakes is identical. One flake gets completely oxidized while the other still have an un-oxidized sp 2 graphitic domain in it. This uneven sp 2 to sp 3 ratio may be the reasons behind two distinct bandgap of GO nanosheets 63,70,71 . In other words, by decreasing concentration of oxidizing agent, there is shrinkage in both band edges of each GO nanosheet samples that may be due to altering the sp 2 /sp 3 ratio or may be the lesser amount of functional groups attached to the basal plane of GO nanosheets 42 .At this point if the amount of oxidant is further decreased exfoliation efficiency got effected and the graphite flacks gets only edge oxidation 24 . This rise in sp 2 domain size induces hydrophobic behavior in to the material resulting in the loss of ability of the synthesized GO to dissolve in the polar solvents under normal conditions. Due to this reason UV absorption spectra could not be found for the samples made using less than 30% (1.8 wt. equiv.) of KMnO 4 . Here, we found an interesting correlation and trend that interplanar distance (extracted from XRD data), FWHM of D-band/G-band (dig out from Raman spectra) and band edges (calculated from UV-Vis absorption data) are increased with increasing the concentration of oxidizing agent KMnO 4 and vice versa. Figure 11c represents the relative band gaps of GO nanosheets and GO/Iron-oxide nanocomposite samples. Sudden decrease in bandgap values of 0.25% iron oxide-99.75%GO nanocomposite is observed for both the secondary and primary band edges from 3.93 and 2.8 eV of pure GO to 3.47 and 2.2 eV respectively. This sudden change in electronic property even for 0.25% loading of iron oxide nanoparticles is because of the greater surface area of nanoparticles that allows greater interaction and more possibility of electronic transfer. Same trend was observed for other nanocomposite samples. Tauc plot of as synthesized Iron Oxide nanoparticles were plotted (not shown here) and the linear extrapolation of this graph gives a value of 1.5 eV which is smaller than 1.92 eV of www.nature.com/scientificreports/ both the major and minor bandgaps. This decrease in bandgaps is even greater than that of 7% iron oxide/93% GO nanocomposites. XRD analyses of 5% iron oxide-95% GO eliminates the possibility of bandgap reduction because of the increased sp 2 /sp 3 ratio caused by the in situ reduction of GO flakes during nanocomposite synthesis www.nature.com/scientificreports/ process. Bandgaps of 7% nanocomposite is greater than the bandgap of 5% nanocomposite. This sudden increase in bandgap apart from increased loading reveals that 5% loading of iron oxide nanoparticles in GO is an optimum loading amount at which the nanocomposite shows the most decrease in bandgap values. These results have been verified by repeating the sample synthesis and characterizations at same parameters. XRD analysis performed previously reveals that GO is not reduced into r-GO in our composite sample formation. So the only reason behind any change in optical bandgap is because of the electronic transitions between the Fe 2 O 3 /Fe 3 O 4 nanoparticles and GO nanosheets in nanocomposite samples. The optical bandgap of GO is far greater than it is required to operate as a semiconductor in optoelectronic devices. This bandgap can be reduced by controlling oxidation level in GO but it has its limitations as discussed. Another way to reduce is optical bandgap is by the incorporation of nano-scaled oxide particles that have a narrow energy gap 73 . Iron Oxide nanoparticles have ability to reduce GO in r-GO. In this article, we have carefully devised a method to incorporate Iron oxide nanoparticles in GO without its in-situ reduction. Mechanism behind this reduction in bandgap can be deeply understood by understanding band edge positions of iron oxide nanoparticles and GO. Band edge position on NHE are theoretically calculated and are shown in Fig. 12 and given in Table 1. Conduction band edge and valence band edge potentials for α-Fe 2 O 3 and Fe 3 O 4 are calculated using the absorption data and using the equation given below 74   75 . E c is the scaling factor for converting absolute vacuum scale to NHE and its value is 4.5 eV. Band edge position of GO are taken from 76 . Band edge positions given in Fig. 12 provide us insight about the mechanism governing the decrease in bandgap of the nanocomposite. The conduction band edge of GO mainly formed by the anti-bonding π* orbitals is at − 0.52 eV, whereas for α-

Conclusion
In this report, we conclude that it is possible to alter the optical bandgap of GO without subjecting it to thermal or chemical reduction. To tailor optical bandgap of GO, four samples of GO are synthesized by Improved Hummer's method utilizing 100, 40, 30 and 20% of the prescribed amount of KMnO 4 . X-ray diffraction (XRD) examination discloses the presence small un-oxidized graphitic domain (002) with prominent (001) plane of GO all over the flakes which in turn affects the exfoliation efficiency and hydrophilic properties except at 100% KMnO 4 we observed pure GO (001) nanosheets. The XRD analysis also proves this controlled oxidation as the interplanar distance is found to decrease along with the oxidizing agent. But the presence of (002) Graphite peak in lower oxidized GO nanosheets points towards the shortcoming of this process. Raman spectroscopy reveals a linear decrease in I D /I G ratio and linear increase in FWHM of D and G peaks as the amount of KMnO 4 is increased, representing a linear increase in degree of oxidation or sp 2 /sp 3 hybridization ratio. Optical bandgap calculated with the help of Absorption spectroscopy also shows a linear decrease as the amount of KMnO 4 is decreased. Limited control over the optical bandgap and compromised exfoliation efficiency made us to look for alternative approaches such as nanocomposites of GO with iron oxide nanoparticles. A novel synthesis process for GO/Iron-oxide nanocomposites named as "Wet impregnation method" is devised that uses pre-synthesized Iron oxide nanoparticles. XRD analysis of synthesized nanocomposites ruled out the possibility of in situ reduction of GO. SEM ruled out all the possibilities of agglomeration of iron oxide nanoparticles and coagulation of GO nanosheets. EDX analysis confirmed the wt.% of constituent elements in all samples while elemental mapping showed the even distribution of nanoparticles throughout the GO nanosheets. Raman spectroscopy confirmed the fairly constant I D /I G ratio and FWHM of D and G peaks, thus proving the fact that the synthesis process of nanocomposites has no effect on the degree of oxidation of GO flakes. Red shift in G peak position of all the nanocomposites synthesized using Wet impregnation method showed the electronic interaction among the constituents of the nanocomposite. Linear decrease in the intensity of PL spectra as the loading of Iron oxide nanoparticles is increased points toward the increased interaction among the iron oxide nanoparticles and GO flakes. Optical bandgap revealed the linear decrease with increasing of Iron oxide nanoparticles from 0.25 to 7% and we noted maximum shift to 0.99 eV in primary bandgap edge of 5% ironoxide/95% GO nanosheet sample.

Synthesis of graphene oxide (GO).
According to Ayrat et al. 24 Potassium Permanganate(KMnO 4 ) is the main oxidizing agent in the synthesis of GO by Tour's method (Improved Hummer's method) and by changing the amount of KMnO 4 degree of oxidation could be altered. We used improved hummer's method but instead of using complete 6 wt. equiv. of KMnO 4 decreased amount is used. Four experiments were carried out by incorporating 3 (50%-GO), 2.4 (40%-GO), 1.8 (30%-GO) and 1.2 (20%-GO)wt. equiv. of KMnO 4 or in other words 1.5, 1.2, 0.9 and 0.6 g of KMnO 4 was used for each 0.5 g batch of graphite. Apart from this modification, each step was followed and every composition was followed according to the prescribed Tour's or Improved hummer's method.
To synthesize GO nanosheets, 2-g of graphite powder was slowly added in to the acid mixture of 270-ml of concentrated sulfuric acid (H 2 SO 4 ) and 30-ml of concentrated phosphoric acid (H 3 PO 4 ). During that addition vigorous stirring is done with the help of magnetic stirrer to avoid agglomeration. In this step acid molecules seep between the graphite layers and thus confirmed making an intercalation compound. After that the solution was kept in an ice bath to lower its temperature to about 10 °C. As the temperature drops 12-g of Potassium Permanganate (KMnO 4 ) was slowly added in to the acid solution in such a manner that temperature never rises above 20 °C during this exothermic reaction. After this addition, solution turned to dark green color. To achieve complete oxidation, solution was heated to about 50 °C and stirred for 12 h. Then 250 ml of deionized water was slowly added while keeping the mixture on ice bath followed by the addition of 6 ml hydrogen peroxide (H 2 O 2 ). This H 2 O 2 neutralizes the oxidizing permanganate ions and stops the oxidation reaction, which was indicated by the change in color from dark green to yellow. At this point solution was washed with deionized water with www.nature.com/scientificreports/ the help of a centrifuge until the pH of the solution reaches to 7. The resultant slurry is then dried in a vacuum oven below 60 °C. Dried GO powders were finely ground and used for further characterizations.

Synthesis of iron oxide nanoparticles.
To synthesize iron oxide nanoparticles co-precipitation technique was used 78 . In this regard aqueous solutions of FeCl 3 6H 2 O (1.54 g/10 ml) and FeCl 2 (0.56 g/10 ml) were made and added in to 150 ml of deionized water to start precipitation 25% ammonium hydroxide (NH 4 OH) was added slowly and pH of solution was maintained to 10. Solution was heated to 90 °C and 3-ml Hydrazine hydrate was added to prevent further oxidation of Fe 3 O 4 nanoparticles and stirred for four hours then products was cooled to room temperature and filters washed with the help of repeated deionized water and absolute alcohol cycles. The remaining black brownish precipitates were then annealed at 450 °C for 3 h to improve crystallinity.

Synthesis of GO/Iron-oxide nanocomposites.
For the synthesis of nanocomposites series of GO/Ironoxide, the suspensions of GO and Iron-oxide nanoparticles were mixed together in DI water with the help of ultra-sonicator bath in a ratio defined by the given empirical formula; This sonication was performed at room temperature for 45 min. The resultant was then placed in autoclave at 65 °C for two hours and then dried in a hot air oven at 100 °C.
Characterization techniques. In this study Powder X-ray diffractometer from BRUKER D8 was used to perform the measurements. This diffractometer have a Copper (Cu) X-ray tube and an incident beam graphite monochromator, with Cu K(α) radiation operating at 45 kV and 40 mA. All the samples were scanned for 2θ value of 5 • to 80 • with a scanning resolution of 0.02 • .UV-vis absorption spectra (1 nm resolution) were acquired using UV-vis spectroscopy (Analytik Jena Specord 200 Plus UV-vis-NIR absorption spectrometer), utilizing quartz cuvettes with optical path lengths of 10 mm. For analysis 70 ppm solutions of all the materials are made using deionized water as a solvent. These solutions were then subjected to 25 min of ultra-sonication to achieve complete dispersion of the material. This process is carried out at room temperature to avoid thermally induced reduction of GO. Field Emission Scanning Electron Microscopy (FE-SEM) and energy dispersive spectroscopy (EDS) measurements were performed to study morphology and elemental distribution of GO and GO/Iron oxide nanocomposite. SEM was performed at a resolution of 10um, 5um, 2um and 1um.Raman spectrophotometer was used to observe degree of oxidation in our samples at room temperature with LASER excitation wavelength of 514 nm.

Data availability
The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.